Cervical spine spacer

ABSTRACT

A cervical spine spacer includes a spacer body configured to be disposed between adjacent cervical vertebrae in the cervical spine and to maintain a desired spacing between the adjacent cervical vertebrae. The cervical spine spacer also includes a channel passing completely through the spacer body from a first surface of the spacer body to a second surface of the spacer body and a fastener configured to pass through the channel. At least one of the first surface and the second surface is configured to contact one of the adjacent cervical vertebrae and the channel is sized to accommodate the fastener passing through the channel at a plurality of angles.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.14/559,944 filed on Dec. 4, 2014 (published as U.S. Patent PublicationNo. 2015/0112386), which is a continuation of U.S. patent applicationSer. No. 13/303,786 filed Nov. 23, 2011 (now issued as U.S. Pat. No.8,926,666), the contents of all of which are incorporated herein byreference in their entirety for all purposes.

FIELD OF THE INVENTION

The present invention relates to cervical spine stabilization andspacing devices.

BACKGROUND OF THE INVENTION

The top seven vertebrae in the spine, vertebrae C1 through C7, form thecervical spine. Adjacent vertebrae in the cervical spine interface attwo sets of opposing articulated surfaces each with an intervertebraldisc. Trauma to the cervical spine, degenerative conditions such asarthritis and genetic disorders can cause fractures in the vertebrae,damage to intervertebral discs, pressure on the spinal cord or othernerves and misalignment or improper spacing between adjacent vertebrae.The result is pain, discomfort and other symptoms including periods ofconfusion or conscious awareness that does not seem normal, difficultyswallowing or saying words due to loss of muscle control after damage tothe nervous system (dysarthria), dizziness, loss of sensation, pain inthe back of the head, loss of the ability to know how joints arepositioned, tingling or numbness in the hands or fingers, tingling ornumbness in the arms, tingling when the neck bends forward or backwardand weakness or stiff and awkward movements of the of the arms and legs.

One such condition is basilar invagination, which occurs when the top ofthe C2 vertebra, e.g., the axis, migrates upward toward the C1 vertebra,e.g., the atlas. As the base of the skull rests on the C1 vertebra andthe odontoid process extends from the axis up though the atlas, thisupwards migration can cause the opening in the skull where the spinalcord passes through to the brain to narrow and may also press on thelower brainstem. Treatment for basilar invagination and other symptomsassociated with other conditions in the cervical spine includes bothsurgical and non-surgical techniques.

While some patients respond well to non-surgical treatments, othersrequire surgery. These surgical techniques include replacing discs andrepairing vertebrae using bone grafts. A cervical plate is screwed intothe superior and inferior vertebral bones, which stabilizes the cervicalspine facilitating fusion and healing. In addition, screws are used tomend fractured vertebrae including a fractured odontoid process.Maintaining proper alignment and spacing between adjacent vertebralbones is important. The use of a screw passing between the adjacentarticular facets does not guarantee that the proper spacing ismaintained. In addition, re-establishing and maintaining proper spacingbetween the axis and the atlas can prevent or alleviate basilarinvagination.

SUMMARY OF THE INVENTION

Exemplary embodiments of the present invention are directed to cervicalspine spacers that maintain or re-establish proper spacing betweenadjacent vertebrae in the cervical spine. These cervical spine spacerscan be used in combination with bone grafts, stabilizing the cervicalspine and acting as a cover or sheath for the bone graft. In addition,these cervical spine spacers accommodate the geometries found betweenadjacent articular facets all along the cervical spine and allow passageof a screw through the spacer at a variety of angles. In one embodiment,these cervical spine spacers can be used between the bodies of thecervical vertebrae at locations other than between opposing articularfacets.

The present invention is directed to a cervical spine spacer having aspacer body configured to be disposed between adjacent cervicalvertebrae in the cervical spine and to maintain a desired spacingbetween the adjacent cervical vertebrae and a channel passing completelythrough the spacer body from a first surface of the spacer body to asecond surface of the spacer body. At least one of the first surface andthe second surface of the spacer body is configured to contact one ofthe adjacent cervical vertebrae. The cervical spine spacer also includesa fastener extending completely through the channel and configured toanchor the spacer body between the adjacent cervical vertebrae. Thechannel is configured to accommodate a fastener extending through thechannel and intersecting each one of the first surface and the secondsurface at a plurality of different angles.

In one embodiment, the first surface is configured to contact a firstcervical vertebra, and the second surface is configured to contact asecond cervical vertebra. Suitable first cervical vertebra include theC1, C2, C3, C4, C5 and C6 vertebra, and suitable second cervicalvertebra include the C2, C3, C4, C5, C6 and C7 vertebra. In oneembodiment, the first surface is configured to contact an inferiorarticular facet of the first cervical vertebra, and the second surfaceis configured to contact a superior articular facet of the secondcervical vertebra. For example, the first cervical vertebra is the C1vertebra and the second cervical vertebra is the C2 vertebra.

In one embodiment, the first surface includes a plurality of pointedprotrusions extending out from the first surface and configured tocontact the first cervical vertebra, and the second surface alsoincludes a plurality of pointed protrusions extending out from thesecond surface and configured to contact the second cervical vertebra.In one embodiment, the channel includes a first opening in the firstsurface and a second opening in the second surface. The first openingextends from a front face of the spacer body partially across the firstsurface towards a back face of the spacer body, and the second openingis disposed in the second surface and extends from the back facepartially across the second surface. The back face is opposite the frontface, and the back face and the front face extend between the firstsurface and the second surface. In one embodiment, the first openingextends partially along the front face from the first surface toward thesecond surface, and the second opening extends partially along the backface from the second surface toward the first surface.

In one embodiment, the front face has a first height between the firstsurface and the second surface, and the back face has a second heightbetween the first surface and the second surface. The first height isless than the second height.

In one embodiment, the spacer body has a spacer portion configured to bedisposed between the adjacent cervical vertebrae and an anchor plateportion extending from the spacer portion, the channel passing throughthe anchor plate portion. The anchor plate portion extends from thespacer portion at an angle of about 90°. The adjacent cervical vertebraeare the C1 vertebra and the C2 vertebra, and the first surface of thespacer body is located on the anchor plate portion and is configured tocontact an anterior surface of the C2 vertebra. The channel passesthrough the anchor plate portion intersecting the first surface and thesecond surface at an angle configured to direct a fastener through theanterior surface of the C2 vertebra from an inferior position toward anodontoid process of the C2 vertebra.

In one embodiment, the spacer body comprises two spacer portions. Theanchor plate portion is U-shaped having two arms, and each spacerportion extends from a given arm of the U-shaped anchor plate portion atthe 90° angle. The spacer portion is configured to be disposed betweenan anterior arch of the C1 vertebra and the body of the C2 vertebrabetween one of a pair of superior articular facets and the odontoidprocess. When the spacer body includes two spacer portions, each spacerportion extends from the anchor plate and is disposed between theanterior arch of the C1 vertebra and the body of the C2 vertebra suchthat each spacer body is on an opposite side of the odontoid process.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a top perspective view of an embodiment of a cervical spinespacer in accordance with the present invention;

FIG. 2 is a bottom perspective view of the embodiment of FIG. 1;

FIG. 3 is a top view of the embodiment of FIG. 1;

FIG. 4 is bottom view of the embodiment of FIG. 1;

FIG. 5 is a front elevation view of the embodiment of FIG. 1;

FIG. 6 is a back elevation view of the embodiment of FIG. 1;

FIG. 7 is a side elevation view of the embodiment of FIG. 1;

FIG. 8 is cross section view of an embodiment of a cervical spine spacerin accordance with the present invention including a fastener;

FIG. 9 is a front elevation view of another embodiment of the cervicalspine space in accordance with the present invention;

FIG. 10 is a view through line 10-10 of FIG. 9;

FIG. 11 is a top perspective view of another embodiment of a cervicalspine spacer in accordance with the present invention;

FIG. 12 is a top view of the embodiment of FIG. 11;

FIG. 13 is a side elevation view of the embodiment of FIG. 11;

FIG. 14 is a view through line 14-14 of FIG. 12;

FIG. 15 is a back elevation view of the embodiment of FIG. 11;

FIG. 16 is a view through line 16-16 of FIG. 15;

FIG. 17 is a representation of an embodiment of a pair of cervical spinespacers between two cervical vertebrae in accordance with the presentinvention;

FIG. 18 is a representation of an embodiment of a cervical spine spacerbetween the atlas and the axis in accordance with the present invention;

FIG. 19 is a representation illustrating a perspective view of anotherembodiment of the cervical spine spacer in accordance with the presentinvention;

FIG. 20 is a representation illustrating a lateral view of the cervicalspine spacer embodiment of FIG. 19 disposed between the atlas and theaxis;

FIG. 21 is a representation illustrating an anterior view of thecervical spine spacer embodiment of FIG. 19 disposed between the atlasand the axis; and

FIG. 22 is a view through line 22-22 of FIG. 21.

DETAILED DESCRIPTION

Referring initially to FIGS. 1-7, an exemplary embodiment of a cervicalspine spacer 100 in accordance with the present invention isillustrated. The cervical spine spacer includes a spacer body 110. Thespacer body is configured to be disposed between and to fit betweenadjacent cervical vertebrae in the cervical spine. These adjacentcervical vertebrae include a first cervical vertebra that can be the C1,C2, C3, C4, C5 or C6 vertebra and a second cervical vertebra that can bethe C2, C3, C4, C5, C6 or C7 vertebra. In one embodiment, the firstcervical vertebra is the C1 vertebra, and the second cervical vertebrais the C2 vertebra. The spacer body is sized and shaped to maintain orto re-establish a desired spacing between the adjacent cervicalvertebrae. Therefore, the spacer body is constructed from a materialthat is suitable to be inserted into the cervical spine and that canwithstand the movement and forces between adjacent vertebrae in thecervical spine. Suitable materials include, but are not limited tometals such as metals such as titanium and stainless steel, plastics andpolymers such as PEEK and PET, Bionate and elastomers.

The spacer body 110 includes a first surface 120 and a second surface130 opposite the first surface. When placed between a given pair ofadjacent vertebrae in the cervical spine, at least one of the firstsurface and the second surface is in contact with one of the vertebraein that given pair of adjacent vertebrae. The first and second surfacescan contact any portion of a given cervical vertebra, including thebody, the anterior arch, the posterior arch, the anterior tubercle, theposterior tubercle, the lateral mass and the transverse process. In oneembodiment, the adjacent cervical vertebrae are contacted at opposingarticular surfaces or articular facets, for example, an inferiorarticular facet of the first cervical vertebra and an opposing superiorarticular facet on the second cervical vertebra. In one embodiment, boththe first surface and second surface contact one of the vertebrae in thegiven pair of adjacent cervical vertebrae.

The spacer body 110 also includes a front face 150 and a back face 160opposite the front face. The front and back faces extend between thefirst and second or top and bottom surfaces of the spacer body. In oneembodiment, the back and front faces extend generally perpendicular tothe first and second surfaces, although the front and back faces canintersect the first and second surfaces at angles other than 90 degrees.In one embodiment, the front and back faces are configured to be alignedwith the anterior and posterior sides of the cervical spine when thecervical spacer is placed between adjacent cervical spine vertebrae. Thespacer body also includes a pair of opposing side faces 170 that alsoextend from the first surface to the second surface. Each side face runsfrom the front face to the back face. In one embodiment, the side facesextend generally perpendicular to the first and second surfaces,although the side faces can intersect the first and second surfaces atangles other than 90 degrees. In one embodiment, the transitions betweenthe first and second surfaces and the front face, the back face and theside faces include a beveled edge 180. The spacer body thus includes abeveled edge that rounds around at least a portion of the perimeter ofthe first surface and the second surface. This beveled edgeadvantageously minimizes or eliminates sharp edges that could hinderinsertion of the spacer body or that could scrape the vertebrae. In oneembodiment, the side faces are configured to be aligned with the lateralsides of the cervical spine when the cervical spacer is placed betweenadjacent cervical spine vertebrae.

The spacer body is generally rectangular or square in shape; however,the transitions, e.g., the corners of the rectangular shape, between thefront and back faces and the side faces are rounded. In someembodiments, the transitions between the front face and the side facesand the back face and the side faces are not identical. Therefore, thespacer body is not symmetrical front to back; however, the spacer bodyis preferably symmetrical side to side. In one embodiment, the roundedtransitions from the side faces to the front face have a greater radiusor are smoother than the rounded transitions from the side faces to theback face. Therefore, the front face of the spacer body has a morerounded appearance, and the back face has a more squared appearance. Ingeneral, the shape of the spacer body, including the transitions amongthe faces, is chosen such that it mirrors or conforms to the shape ofthe portion of the cervical spine vertebrae that it contacts. Forexample, the transitions among the faces are configured to fit betweenopposing articular facets within the space occupied by intervertebraldiscs. In addition, all of the dimensions of the spacer body areselected to fit within the space between opposing articular facets.

In one embodiment, the spacer body includes a plurality of pointedprotrusions 190 located on at least one of the first surface and thesecond surface. In some embodiments, the pointed protrusions are locatedon both the first surface and the second surface. In one embodiment,each pointed protrusion is shaped as a pyramid having a square orrectangular base and extends out from the first or second surface. Thepyramid shape can be truncated, e.g., frusto-conical, and the pyramidshaped pointed protrusions along the edges of the spacer body can beshaved or clipped by the beveled edge of the spacer body. The pointedprotrusions are configured to contact the first cervical vertebra andthe second cervical vertebra in the adjacent pair of cervical vertebraebetween which the spacer body is positioned. This assists in holding thespacer body in place and prevents undesired movement between the spacerbody and the cervical vertebrae.

The spacer body includes a groove 200 running along each side face andextending into the spacer body. The groove has a rectangular or roundedcross section and preferably extends along the entire length of eachside face. The groove removes mass from the spacer body and alsoprovides a surface for gripping the spacer body using an insertion toolsuch that the insertion tool does not extend outside the dimensions ofthe spacer body. At least one and preferably two holes 210 are providedpassing completely through the spacer body. These holes extend throughthe spacer body perpendicular to the grooves, and the ends of the holesare located in the grooves. These holes also provide a gripping surfacefor an insertion tool and also provide access to structures such as bonegrafts that are surrounded by or contained within the spacer body.

The spacer body is configured to have a desired thickness or height 220(FIG. 5) defined between the first surface and the second surface. Thisthickness is selected based upon the desired spacing to be maintained orestablished between the adjacent cervical vertebrae. Therefore, theselected thickness can vary depending on the exact vertebra in theadjacent pair of vertebrae and on the location of the cervical spacerbetween the adjacent pair of vertebrae, e.g., between opposing articularfacets or between opposing transverse processes. In one embodiment, thethickness is constant between the side faces or the spacer body butvaries between the front face 150 and the back face 160 (FIG. 7). Forexample, the thickness is smaller at the front face and larger at theback face. In one embodiment, the front face has a first height 141between the first surface and the second surface, and the back face hasa second height 142 between the first surface and the second surface.The first height is less than the second height. The difference inthickness represents an angle 140 between the first surface and thesecond surface when moving from the front face to the back face. Thisangle can be varied and matches, for example, changes in distancebetween opposing portions of the adjacent vertebrae such as opposingarticular facets. In one embodiment, this angle is between about 5° andabout 10°, preferably about 7°. The spacer body can also include steeperor larger beveled surfaces 230, 231 adjacent the front face between thefirst surface and the second surface. This larger beveled surface islarger than the beveled perimeter 180 and facilitates insertion of thespacer body between the adjacent cervical vertebrae.

The cervical spine spacer 100 also includes a channel 240 passingcompletely through the spacer body 110 from the first surface of thespacer body to the second surface of the spacer body. The channel 240includes a first opening 241 in the first surface and a second opening242 in the second surface. In one embodiment, the first opening andsecond opening are completely contained within the first surface and thesecond surface and do not extend to the edges of the first and secondsurfaces. Preferably, the first opening extends from the front face,e.g., the edge where the front face meets the first surface, of thespacer body partially across the first surface towards a back face ofthe spacer body. Similarly, the second opening extends from the backface, e.g., the edge where the back face meets the second surface,partially across the second surface toward the front face. In someembodiments, the first opening does not extend completely to the backface, and the second opening does not extend completely to the frontface. In addition, both the first and second openings do not extendcompletely to the side faces.

In one embodiment, the first opening includes a front face portion 143that extends partially along the front face from the first surfacetoward the second surface, and the second opening includes a back faceportion 144 that extends partially along the back face from the secondsurface toward the first surface. Although the channel extends along thefront face and the back face, the channel is completely enclosed by thespacer body.

Referring to FIG. 8, in one embodiment, the cervical spine spacerincludes at least one fastener 250. Suitable fasteners and fastenermaterials for use with spinal implants are known and available in theart and include screws such as titanium screw. The fastener isconfigured to pass completely through the channel 240 and into at leastone or both of the vertebrae in the adjacent pair of cervical vertebrae.Therefore, the fastener has an overall length sufficient to extendthrough the spacer body and into the cervical vertebrae. In oneembodiment, this length is sufficient to pass through the firstvertebra, through the channel and into the second vertebra. In oneembodiment, the channel is also configured to be large enough tosurround or act as a sheath for a bone graft placed between the adjacentvertebrae. As the geometry of the spine varies depending on the locationof the cervical spine spacer, and the fastener may be inserted into thevertebrae and through the channel from a variety or directions, e.g.,anterior, posterior, lateral, superior and inferior, the angle 252between the fastener and at least one of the first surface and thesecond surface will vary. Therefore, the channel is configured toaccommodate a fastener extending through the channel and intersectingeach one of the first surface and the second surface at a plurality ofdifferent angles. The larger the first and second openings of thechannel, the greater the range of angles accommodated. By including thefront face portion and the back face portion of the first and secondopenings, and even greater range of angles is accommodated. Inparticular, rather small angles are accommodated as would be found inapplications where the interface, e.g., the opposing articular facets,forms an angle of less than 45% with the axis of the cervical spine. Italso accommodates approaching a cervical spacer from the front face ofthe back face at a rather shallow angle.

As discussed above, the thickness of the spacer body is varied dependingon the desired spacing and the location of the spacer along the cervicalspine. Referring to FIGS. 9 and 10, another embodiment of a cervicalspine spacer 300 in accordance with the present invention isillustrated. The cervical spine spacer 300 includes a spacer body 310configured to be disposed between and to fit between adjacent cervicalvertebrae in the cervical spine. These adjacent cervical vertebraeinclude a first cervical vertebra that can be the C1, C2, C3, C4, C5 orC6 vertebra and a second cervical vertebra that can be the C2, C3, C4,C5, C6 or C7 vertebra. In one embodiment, the first cervical vertebra isthe C1 vertebra, and the second cervical vertebra is the C2 vertebra.The spacer body is sized and shaped to maintain or to re-establish adesired spacing between the adjacent cervical vertebrae. Therefore, thespacer body is constructed from a material that is suitable to beinserted into the cervical spine and that can withstand the movement andforces between adjacent vertebrae in the cervical spine. Suitablematerials include, but are not limited to metals such as stainless steeland titanium, plastics and polymers, and elastomers.

The spacer body 310 includes a first surface 320 and a second surface330 opposite the first surface. When placed between a given pair ofadjacent vertebrae in the cervical spine, at least one of the firstsurface and the second surface is in contact with one of the vertebraein that given pair of adjacent vertebrae. The first and second surfacescan contact any portion of a given cervical vertebra, including thebody, the anterior arch, the posterior arch, the anterior tubercle, theposterior tubercle, the lateral mass and the transverse process. In oneembodiment, the adjacent cervical vertebrae are contacted at opposingarticular surfaces or articular facets, for example, an inferiorarticular facet of the first cervical vertebra and an opposing superiorarticular facet on the second cervical vertebra. In one embodiment, boththe first surface and second surface contact one of the vertebra in thegiven pair of adjacent cervical vertebrae.

The spacer body 310 also includes a front face 350 and a back face 360opposite the front face. The front and back faces extend between thefirst and second or top and bottom surfaces of the spacer body. In oneembodiment, the back and front faces extend generally perpendicular tothe first and second surfaces, although the front and back faces canintersect the first and second surfaces at angles other than 90 degrees.In one embodiment, the front and back faces are configured to be alignedwith the anterior and posterior sides of the cervical spine when thecervical spacer is placed between adjacent cervical spine vertebrae. Thespacer body also includes a pair of opposing side faces 370 that alsoextend from the first surface to the second surface. Each side face runsfrom the front face to the back face. In one embodiment, the side facesextend generally perpendicular to the first and second surfaces,although the side faces can intersect the first and second surfaces atangles other than 90 degrees. In one embodiment, the transitions betweenthe first and second surfaces and the front face, the back face and theside faces include a beveled edge 380. Therefore, the spacer bodyincludes a beveled edge that rounds around the perimeter of the firstsurface and the second surface. This beveled edge minimizes oreliminates sharp edges that could hinder insertion of the spacer body orthat could scrape the vertebrae. In one embodiment, the side faces areconfigured to be aligned with the lateral sides of the cervical spinewhen the cervical spacer is placed between adjacent cervical spinevertebrae.

The spacer body is generally rectangular or square in shape; however,the transitions, e.g., the corners of the rectangular shape, between thefront and back faces and the side faces are rounded. The transitionsbetween the front face and the side faces and the back face and the sidefaces are not identical. Therefore, the spacer body is not symmetricalfront to back; however, the spacer body is preferably symmetrical sideto side. In one embodiment, the rounded transitions from the side facesto the front face have a greater radius or are smoother than the roundedtransitions from the side faces to the back face. Therefore, the frontface of the spacer body has a more rounded appearance, and the back facehas a more squared appearance. In general, the shape of the spacer body,including the transitions among the faces is chosen such that it mirrorsor conforms to the shape of the portion of the cervical spine vertebraethat it contacts. For example, the transitions among the faces areconfigured to fit between opposing articular facets within the spaceoccupied by intervertebral discs. In addition, all of the dimensions ofthe spacer body are selected to fit within the space between opposingarticular facets.

In one embodiment, the spacer body includes a plurality of pointedprotrusions 390 located on at least one of the first surface and thesecond surface. Preferably, the pointed protrusions are located on boththe first surface and the second surface. In one embodiment, eachpointed protrusion is shaped as a pyramid having a square or rectangularbase and extends out from the first or second surface. The pyramid shapecan be truncated 391, e.g., frusto-conical, and the pyramid shapedpointed protrusions along the edges of the spacer body can be shaved orclipped by the beveled edge of the spacer body. The pointed protrusionsare configured to contact the first cervical vertebra and the secondcervical vertebra in the adjacent pair of cervical vertebrae betweenwhich the spacer body is positioned. This assists in holding the spacerbody in place and prevents undesired movement between the spacer bodyand the cervical vertebra.

The spacer body includes a groove 400 running along each side face andextending into the spacer body. The groove has a rectangular or roundedcross section and preferably extends along the entire length of eachside face. The groove removes mass from the spacer body and alsoprovides a surface for gripping the spacer body using an insertion toolsuch that the insertion tools does not extend outside the dimensions ofthe spacer body. At least one hole 410 is provided passing completelythrough the spacer body. The hole extends through the spacer bodyperpendicular to the grooves, and the ends of the hole are located inthe grooves. The hole also provides a gripping surface for an insertiontool and also provides access to structures such as bone grafts that aresurrounded by or contained within the spacer body.

The spacer body is configured to have a desired thickness or height 420defined between the first surface and the second surface. This thicknessis selected based upon the desired spacing to be maintained orestablished between the adjacent cervical vertebrae. Therefore, theselected thickness can vary depending on the exact vertebra in theadjacent pair of vertebrae and on the location of the cervical spacerbetween the adjacent pair of vertebrae, e.g., between opposing articularfacets or between opposing transverse processes. As illustrated, thisthickness 420 is greater than the thickness in the previously describedcervical spine spacer 100 embodiment. Therefore, the present embodimentaccommodates a large spacing or gap between adjacent cervical vertebrae.In addition, this greater thickness, allows for larger front face andback face portions of the channel openings.

In one embodiment, the thickness is constant between the side faces orthe spacer body but varies between the front face 350 and the back face360. For example, the thickness is smaller at the front face and largerat the back face. In one embodiment, the front face has a first height341 between the first surface and the second surface, and the back facehas a second height 342 between the first surface and the secondsurface. The first height is less than the second height. The differencein thickness represents an angle 340 between the first surface and thesecond surface when moving from the front face to the back face. Thisangle can be varies and matches, for example, changes in distancebetween opposing portions of the adjacent vertebrae such as opposingarticular facets. The spacer body can also include steeper or largerbeveled surfaces 430, 431 adjacent the front face between the firstsurface and the second surface. This larger beveled surface is largerthan the beveled perimeter 380 and facilitates insertion of the spacerbody between the adjacent cervical vertebrae.

The cervical spine spacer 300 also includes a channel 440 passingcompletely through the spacer body 310 from the first surface of thespacer body to the second surface of the spacer body. The channel 440includes a first opening 441 in the first surface and a second opening442 in the second surface. In one embodiment, the first opening andsecond opening are completely contained within the first surface and thesecond surface and do not extend to the edges of the first and secondsurfaces. Preferably, the first opening extends from the front face,e.g., the edge where the front face meets the first surface, of thespacer body partially across the first surface towards a back face ofthe spacer body. Similarly, the second opening extends from the backface, e.g., the edge where the back face meets the second surface,partially across the second surface toward the front face. The firstopening does not extend completely to the back face, and the secondopening does not extend completely to the front face. In addition, boththe first and second openings do not extend completely to the sidefaces.

In one embodiment, the first opening includes a front face portion 343that extends partially along the front face from the first surfacetoward the second surface, and the second opening includes a back faceportion 344 that extends partially along the back face from the secondsurface toward the first surface. Although the channel extends along thefront face and the back face, the channel is completely enclosed by thespacer body. In this embodiment, the larger thickness of the spacer bodyyields a larger channel that can accommodate larger bone grafts spanninggreater distances between adjacent cervical vertebrae.

Referring now to FIGS. 11-16, another exemplary embodiment of a cervicalspine spacer 500 in accordance with the present invention isillustrated. This embodiment illustrates a cervical spine spacer that isU-shaped with an open channel to accommodate insertion around a bonegraft or other structure and a greater range of angles between afastener passing through the channel and the spacer body. The cervicalspine spacer includes a spacer body 510. The spacer body is configuredto be disposed between and to fit between adjacent cervical vertebrae inthe cervical spine. These adjacent cervical vertebrae include a firstcervical vertebra that can be the C1, C2, C3, C4, C5 or C6 vertebra anda second cervical vertebra that can be the C2, C3, C4, C5, C6 or C7vertebra. In one embodiment, the first cervical vertebra is the C1vertebra, and the second cervical vertebra is the C2 vertebra. Thespacer body is sized and shaped to maintain or to re-establish a desiredspacing between the adjacent cervical vertebrae. Therefore, the spacerbody is constructed from a material that is suitable to be inserted intothe cervical spine and that can withstand the movement and forcesbetween adjacent vertebrae in the cervical spine. Suitable materialsinclude, but are not limited to metals such as titanium and plastics,polymers and elastomers.

The spacer body 510 includes a first surface 520 and a second surface530 opposite the first surface. When placed between a given pair ofadjacent vertebrae in the cervical spine, at least one of the firstsurface and the second surface is in contact with one of the vertebra inthat given pair of adjacent vertebrae. The first and second surfaces cancontact any portion of a given cervical vertebra, including the body,the anterior arch, the posterior arch, the anterior tubercle, theposterior tubercle, the lateral mass and the transverse process. In oneembodiment, the adjacent cervical vertebrae are contacted at opposingarticular surfaces or articular facets, for example, an inferiorarticular facet of the first cervical vertebra and an opposing superiorarticular facet on the second cervical vertebra. In one embodiment, boththe first surface and second surface contact one of the vertebrae in thegiven pair of adjacent cervical vertebrae.

The spacer body 510 also includes a front face 550 and a back face 560opposite the front face. The front and back faces extend between thefirst and second or top and bottom surfaces of the spacer body. In oneembodiment, the back and front faces extend generally perpendicular tothe first and second surfaces, although the front and back faces canintersect the first and second surfaces at angles other than 90 degrees.In one embodiment, the front and back faces are configured to be alignedwith the anterior and posterior sides of the cervical spine when thecervical spacer is placed between adjacent cervical spine vertebrae. Thespacer body also includes a pair of opposing side faces 570 that alsoextend from the first surface to the second surface. Each side face runsfrom the front face to the back face. In one embodiment, the side facesextend generally perpendicular to the first and second surfaces,although the side faces can intersect the first and second surfaces atangles other than 90 degrees. In one embodiment, the transitions betweenthe first and second surfaces and the front face, the back face and theside faces include a beveled edge 580. Therefore, the spacer bodyincludes a beveled edge that rounds around the perimeter of the firstsurface and the second surface. This beveled edge minimizes oreliminates sharp edges that could hinder insertion of the spacer body orthat could scrape the vertebrae. In one embodiment, the side faces areconfigured to be aligned with the lateral sides of the cervical spinewhen the cervical spacer is placed between adjacent cervical spinevertebrae.

The spacer body is generally rectangular or square in shape; however,the transitions, e.g., the corners of the rectangular shape, between thefront and back faces and the side faces are rounded. The transitionsbetween the front face and the side faces and the back face and the sidefaces are not identical. Therefore, the spacer body is not symmetricalfront to back; however, the spacer body is preferably symmetrical sideto side. In one embodiment, the rounded transitions from the side facesto the front face have a greater radius or are smoother than the roundedtransitions from the side faces to the back face. Therefore, the frontface of the spacer body has a more rounded appearance, and the back facehas a more squared appearance. In general, the shape of the spacer body,including the transitions among the faces is chosen such that it mirrorsor conforms to the shape of the portion of the cervical spine vertebrathat it contacts. For example, the transitions among the faces areconfigured to fit between opposing articular facets within the spaceoccupied by intervertebral discs. In addition, all of the dimensions ofthe spacer body are selected to fit within the space between opposingarticular facets.

In one embodiment, the spacer body includes a plurality of pointedprotrusions 590 located on at least one of the first surface and thesecond surface. Preferably, the pointed protrusions are located on boththe first surface and the second surface. In one embodiment, eachpointed protrusion is shaped as a pyramid having a square or rectangularbase and extends out from the first or second surface. The pyramid shapecan be truncated, e.g., frusto-conical, and the pyramid shaped pointedprotrusions along the edges of the spacer body can be shaved or clippedby the beveled edge of the spacer body. The pointed protrusions areconfigured to contact the first cervical vertebra and the secondcervical vertebra in the adjacent pair of cervical vertebrae betweenwhich the spacer body is positioned. This assists in holding the spacerbody in place and prevents undesired movement between the spacer bodyand the cervical vertebrae.

The spacer body includes a groove 600 running along each side face andextending into the spacer body. The groove has a rectangular or roundedcross section and preferably extends along the entire length of eachside face. The groove removes mass from the spacer body and alsoprovides a surface for gripping the spacer body using an insertion toolsuch that the insertion tools does not extend outside the dimensions ofthe spacer body. At least one and preferably two or more holes 610 areprovided passing completely through the spacer body. These holes extendthrough the spacer body perpendicular to the grooves, and the ends ofthe holes are located in the grooves. These holes also provide agripping surface for an insertion tool and also provide access tostructures such as bone grafts that are surrounded by or containedwithin the spacer body. As illustrated, some holes pass completelythrough the spacer body, or at least completely into the channel, andother holes only extend partially into the spacer body.

The spacer body is configured to have a desired thickness or height 620(FIG. 15) defined between the first surface and the second surface. Thisthickness is selected based upon the desired spacing to be maintained orestablished between the adjacent cervical vertebrae. Therefore, theselected thickness can vary depending on the exact vertebra in theadjacent pair of vertebrae and on the location of the cervical spacerbetween the adjacent pair of vertebrae, e.g., between opposing articularfacets or between opposing transverse processes. In one embodiment, thethickness is constant between the side faces or the spacer body butvaries between the front face 550 and the back face 560 (FIG. 13). Forexample, the thickness is smaller at the front face and larger at theback face. In one embodiment, the front face has a first height 541between the first surface and the second surface, and the back face hasa second height 542 between the first surface and the second surface.The first height is less than the second height. The difference inthickness represents an angle 540 between the first surface and thesecond surface when moving from the front face to the back face. Thisangle can be varied and matches, for example, changes in distancebetween opposing portions of the adjacent vertebrae such as opposingarticular facets. In one embodiment, this angle is between about 5° andabout 10°, preferably about 7°. The spacer body can also include steeperor larger beveled surfaces 630, 631 adjacent the front face between thefirst surface and the second surface. This larger beveled surface islarger than the beveled perimeter 580 and facilitates insertion of thespacer body between the adjacent cervical vertebrae.

The cervical spine spacer 500 also includes a channel 640 passingcompletely through the spacer body 510 from the first surface of thespacer body to the second surface of the spacer body. The channel 640includes a first opening 641 in the first surface and a second opening642 in the second surface. The first opening extends from the back face,e.g., the edge where the back face meets the first surface, of thespacer body partially across the first surface towards a front face ofthe spacer body. Similarly, the second opening extends from the backface, e.g., the edge where the back face meets the second surface,partially across the second surface toward the front face. Both thefirst and second openings for not extend completely to the side faces.Alternatively, both the first and second openings can extend from thefront face toward the back face.

The channel also includes a back face portion 544 that extendscompletely along the back face from the second surface to the firstsurface and is in communication with both the first opening and thesecond opening. Therefore, the channel is not completely enclosed by thespacer body. This yields a spacer body having a distinctive U-shapewithin an open channel. The open channel facilitates insertion of thecervical spine spacer around structures in the cervical spine. Inaddition, an even shallower angle is facilitated between the fastenerand the first or second surfaces of the spacer body.

In one embodiment, the spacer body of all embodiments of the cervicalspine spacer in accordance with the present invention is sized andshaped to fit within the space between the opposing articular facets,for example in the space typically occupied by an intervertebral disc.Referring to FIG. 17, a pair of cervical spine spacers 700 is insertedbetween a first cervical vertebra 701 and a second cervical vertebra702. In some embodiments, the first cervical vertebra can be the C1through C6 vertebrae, and the second cervical vertebra can be the C2through C7 vertebrae. Each spacer is placed between the superiorarticular facet 703 of the first cervical vertebra and the inferiorarticular facet 705 of the second cervical vertebra. A fastener 750,e.g., a screw, can be passed in a direction from the second cervicalvertebra 702, through the spacer 700 and into the second cervicalvertebra 701, e.g., from an inferior position to a superior position. Inother embodiments, the screw can be passed in a direction from the firstcervical vertebra to the second cervical vertebra. The shape of thechannel accommodates the direction of insertion of the fastener, andaccess to the interior of the channel is provided, for example, by theback face portion 705 of the channel opening, which is exposed in aposterior position based on the direction of insertion of the spacer.

Referring to FIG. 18, a cervical spine spacer 800 is inserted between afirst cervical vertebra 801 and a second cervical vertebra 802. Thefirst cervical vertebra is the C1 vertebra or atlas, and the secondcervical vertebra is the C2 vertebra or axis. The spacer is placedbetween the superior articular facet 803 of the first cervical vertebraand the inferior articular facet 805 of the second cervical vertebra. Afastener 850, e.g., a screw, a passed in a direction from the secondcervical vertebra 802, through the spacer 800 and into the firstcervical vertebra 801, e.g., from an inferior position to a superiorposition, as the skull inhibits access in the other direction. The shapeof the channel accommodates this routing of the fastener, and access tothe interior of the channel is provided, for example, by the back faceportion 805 of the channel opening, which is exposed in a posteriorposition based on the direction of insertion of the spacer. Suitablemethods and tools for access the cervical spine, inserting spacers andinserting and securing fasteners are known and available in the art.

Referring to FIGS. 19-22, another exemplary embodiment of a cervicalspine spacer 900 in accordance with the present invention isillustrated. The cervical spine spacer includes a spacer body 910. Thespacer body is configured to be disposed between and to fit betweenadjacent cervical vertebrae in the cervical spine. These adjacentcervical vertebrae include a first cervical vertebra that can be the C1,C2, C3, C4, C5 or C6 vertebra and a second cervical vertebra that can bethe C2, C3, C4, C5, C6 or C7 vertebra. In one embodiment as illustrated,the first cervical vertebra 901 is the C1 vertebra or atlas, and thesecond cervical vertebra 902 is the C2 vertebra or axis. The spacer bodyis sized and shaped to maintain or to re-establish a desired spacingbetween the adjacent cervical vertebrae. Therefore, the spacer body isconstructed from a material that is suitable to be inserted into thecervical spine and that can withstand the movement and forces betweenadjacent vertebrae in the cervical spine. Suitable materials include,but are not limited to metals such as titanium and plastics, polymersand elastomers.

The spacer body 910 includes a first surface 920 and a second surface930 opposite the first surface. When placed between a given pair ofadjacent vertebrae in the cervical spine, the first surface is incontact with one of the vertebrae in that given pair of adjacentvertebrae. In particular, the first surface is in contact with theanterior side of the second cervical vertebrae. The spacer body includesat least one spacer portion 904 configured to be disposed between theadjacent cervical vertebrae and an anchor plate portion 903 extendingfrom the spacer portion. In one embodiment, the anchor plate portionextends from the spacer portion at an angle of about 90°. The firstsurface along the anchor plate portion is in contact with the anteriorsurface of the second or C2 vertebra. The first surface along the spacerportion is in contact with another portion of the second vertebra, andthe second surface is on contact with the first vertebra. In oneembodiment, the spacer body includes two separate and independent spacerportions. The separate and independent spacer portions are disposedbetween different portions of the first and second cervical vertebra.The anchor plate portion is U-shaped having two arms, and each spacerportion extends from a given arm of the U-shaped anchor plate portion atthe 90° angle.

Each cervical spine spacer 900 spacer portion 904 is configured to bedisposed between an anterior arch 905 of the C1 vertebra and the body906 of the C2 vertebra between one of a pair of superior articularfacets 907 and the odontoid process 908. When the spacer body includestwo spacer portions, each spacer portion extends from the anchor plateand is disposed between the anterior arch of the C1 vertebra and thebody of the C2 vertebra such that each spacer body is on an oppositeside of the odontoid process.

The cervical spine spacer 900 also includes a fastener 950 a channel 940passing completely through the spacer body 910 from the first surface ofthe spacer body to the second surface of the spacer body. The channel940 includes a first opening 941 in the first surface and a secondopening 942 in the second surface. The channel is sized and shaped toaccommodate the fastener, which is typically a screw that is passedthrough the channel from the second opening to the first opening andinto the second cervical vertebra. In one embodiment, the fastenerextends into the second cervical vertebra along an axis running throughthe odontoid process along a trajectory that is the same as those ofodontoid screws used to repair a fractured odontoid process. In oneembodiment, the fastener is removed and replaced with a longer odontoidscrew. In one embodiment, the channel passes through the anchor plateportion intersecting the first surface and the second surface at anangle configured to direct a fastener through the anterior surface ofthe C2 vertebra from an inferior position toward the odontoid process ofthe C2 vertebra.

While it is apparent that the illustrative embodiments of the inventiondisclosed herein fulfill the objectives of the present invention, it isappreciated that numerous modifications and other embodiments may bedevised by those skilled in the art. Additionally, feature(s) and/orelement(s) from any embodiment may be used singly or in combination withother embodiment(s) and steps or elements from methods in accordancewith the present invention can be executed or performed in any suitableorder. Therefore, it will be understood that the appended claims areintended to cover all such modifications and embodiments, which wouldcome within the spirit and scope of the present invention.

What is claimed is:
 1. A cervical spine spacer comprising: a spacerbody, including a first surface and a second surface, wherein the firstsurface is configured to contact a first cervical vertebral body amongadjacent cervical vertebral bodies, the spacer body further comprising:a first spacer portion and a second spacer portion; and an anchor plateportion from which the first spacer portion and the second spacerportion extend; and a channel configured to pass through the spacer bodyfrom the first surface and the second surface, wherein the channelcomprises a first opening in the first surface and a second opening inthe second surface, wherein the first spacer portion and the secondspacer portion are coupled only through the anchor plate, and whereinthe anchor plate extends in a plane orthogonal to both the first spacerportion and the second spacer portion.
 2. The cervical spine spacer ofclaim 1, further comprising a fastener extending through the channel andconfigured to anchor the spacer body.
 3. The cervical spine spacer ofclaim 2, wherein the fastener has an overall length sufficient to passthrough the channel in the spacer body into a second vertebra.
 4. Thecervical spine spacer of claim 1, wherein the anchor plate is u-shaped.5. The cervical spine spacer of claim 4, wherein the anchor plate has afirst arm and a second arm, wherein the first spacer portion extendsfrom the first arm at a 90-degree angle.
 6. The cervical spine spacer ofclaim 5, wherein the second spacer portion extends from the second armat a 90-degree angle.
 7. The cervical spine spacer of claim 1, whereinthe first spacer portion and the second spacer portion are configured tobe disposed between an anterior arch of a C1 vertebra and a body of a C2vertebra between a pair of superior articular facets and the odontoidprocess.
 8. The cervical spine spacer of claim 1, further comprising afastener, wherein the channel is wherein the channel is sized and shapedto accept the fastener.
 9. The cervical spine spacer of claim 8, whereinthe fastener is configured to pass through the channel from the secondopening to the first opening into a second vertebral body among theadjacent vertebral bodies.
 10. The cervical spine spacer of claim 9,wherein the fastener is configured to extend into the second vertebraalong an axis running through the odontoid process.
 11. A cervical spinespacer comprising: a spacer body including a first surface and a secondsurface, the spacer body further comprising: a first spacer portion anda second spacer portion; and an anchor plate portion from which thefirst spacer portion and the second spacer portion extend; a channelcomprising a first opening in the first surface and a second opening inthe second surface; a fastener configured to pass through the channel,wherein the first spacer portion and the second spacer portion arecoupled only through the anchor plate, and wherein the anchor plateextends in a plane orthogonal to both the first spacer portion and thesecond spacer portion.
 12. The cervical spine spacer of claim 11,wherein the fastener is configured to anchor the spacer body.
 13. Thecervical spine spacer of claim 12, wherein the fastener has an overalllength sufficient to pass through the channel in the spacer body into asecond vertebra.
 14. The cervical spine spacer of claim 11, wherein theanchor plate is u-shaped.
 15. The cervical spine spacer of claim 14,wherein the anchor plate has a first arm and a second arm, wherein thefirst spacer portion extends from the first arm at a 90-degree angle.16. The cervical spine spacer of claim 15, wherein the second spacerportion extends from the second arm at a 90-degree angle.
 17. Thecervical spine spacer of claim 11, wherein the first spacer portion andthe second spacer portion are configured to be disposed between ananterior arch of a C1 vertebra and a body of a C2 vertebra between apair of superior articular facets and the odontoid process.
 18. Thecervical spine spacer of claim 11, wherein the channel is sized andshaped to accept the fastener, wherein the channel comprises a firstopening on the first surface and a second opening on the second surface.19. The cervical spine spacer of claim 18, wherein the fastener isconfigured to pass through the channel from the second opening to thefirst opening into a second vertebral body among the adjacent vertebralbodies.
 20. The cervical spine spacer of claim 19, wherein the fasteneris configured to extend into the second vertebra along an axis runningthrough the odontoid process.